DE561336C - Electron tubes with cathode, control grid and anode - Google Patents

Description

With electron tubes, which have a hot cathode with one or more others Anodes interacts, it is already known to train the anodes and to-5 arrange that they take its place if the actual hot cathode is destroyed can. The destroyed cathode then takes the place of the anode. All you need is the power connections of the Electrodes to be exchanged for each other. By destroying the original Any interruption of operation occurring at the cathode must then be rectified immediately by swapping the power connections.

According to the invention, this advantage is to be used for an electron tube which is provided with a cathode, a control grid and an anode. Should be with such a Three-electrode tube the control grid in place of the one worn out by burning Cathode step and this take over the role of the control grid, the further requirement must still be met that through this confusion the characteristics of the tube, that is, its penetration, its steepness etc., is not changed. According to the invention this is achieved in that the The cathode and the control grid are designed as emissive electrodes of the same type and their distances from the two associated anodes are essentially the same, so that when swapping their connections, the two electrodes swap their function without

the characteristic of the tube changes significantly. So it's in the making of the Tube with regard to the mutual position of the three electrodes, already taking into account the interchangeability taken from cathode with control grid.

In the case of a three-electrode tube, the grid must also be designed as a heatable incandescent body, is already known per se, but this property of the grating is only used in the Manufacture of the tube used for degassing. It is therefore also the cathode in the usual way as an elongated one Formed thread which is surrounded by the helically wound grid wire. Both electrodes are therefore at different distances from the anode surrounding them, see above that if the power connections are interchanged, the characteristics of the tube are changed would be.

It is also already known in electrical relays, in a degassed tube between two anodes to arrange two cathodes. In this arrangement, however, not one should go through Burning worn cathode take on the role of a control grid, rather it is intended by the known arrangement, by different heating of the cathodes to cause different electron currents.

The drawing shows two exemplary embodiments of the electron tube according to the finding shown.

Fig. Ι shows an embodiment of a three-electrode tube in view.

Fig. 2 shows part of Fig. Ι on a larger scale.

3 shows a further embodiment of the three-electrode system in a diagrammatic manner Representation, and

Figure 4 is the plan of this system. In the three-electrode tube shown in Fig. Ι, z. B. a radio tube, are located inside the anode cylinder ο two helically wound wires ρ and r, which do not touch. The axes of the helical lines of both wires coincide with the axis of the anode cylinder 0 and the diameter of the turns of both wires and their number of turns is approximately the same (FIG. 2). Both wires p and r are designed as heatable incandescent bodies. The ends of the wires are connected to the connector pins of the base, not shown , by power supply lines p ¹ , / r and r ¹ , r ^{2, which also serve as support members.}

During operation, for example, the wire /; as a hot cathode, in that when the tube is inserted into the socket, the pins of the lines / » ¹ and /> ^{2 are} connected to a heating source on the one hand and to the anode circuit on the other. The pins of the lines r ¹ and r ² are then short-circuited in the socket and connected to the grid circuit. The wire r thus interacts with the cathode ρ as a grid.

If the wire p is so worn by burning that it can no longer act as a cathode, the connector pins of the leads p ¹ and p ° are short-circuited, for example, by changing the connections of the socket and placed on the grid circle, while the connector pins of the leads are connected r ¹ and r ^{2 are} canceled and the pins are connected to the heating source. In addition, one of the connector pins ¹ , r ^{2 must then be connected} to the anode circuit. The worn former cathode /) then acts as a grid with the former grid r , which has now become the cathode.

The characteristics of the tube are not changed when the electrodes p and r are exchanged, so the penetration and the slope in particular remain the same as before, since the two wires /) and r both have the same number of turns and the same diameter the same position in relation to the anode cylinder 0 which is jointly assigned to the two wires p, r.

In the embodiment according to FIGS. 3 and 4, wires d and e are stretched out in a zigzag shape within a hollow anode body α, which is rectangular in horizontal cross section, on holding rods & and c, respectively. Both wires are designed as incandescent bodies of the same type, so they have the same length and the same number of turns. The planes of the two wires d, e are parallel to one another and to the longitudinal sides of the hollow anode body a, and both wires are arranged symmetrically to the longitudinal center plane of the hollow anode body α that is assigned to them in common.

First of all, wire d serves as the cathode and wire e as the control grid. If the current connections of the wires d and e are interchanged when the cathode d is worn, so that the wire e acts as the cathode and the wire d as the control grid, the characteristics of the tube are also not changed, since the two wires are of identical design and lie symmetrically to the longitudinal center plane of the hollow anode body a.

Claims (1)

Claim: Electron tube with cathode, control grid and anode, characterized in that that the cathode and the control grid are designed as emissive electrodes of the same type and their spacing of the two associated anodes are essentially the same, so that when their connections are interchanged, the two Electrodes change their function without the characteristic curve of the tube being noticeable changes. 1 sheet of drawings